WO2013160162A1

WO2013160162A1 - Thermomechanical rolling of an aluminium plate

Info

Publication number: WO2013160162A1
Application number: PCT/EP2013/057960
Authority: WO
Inventors: Matthias Kurz; Birger Schmidt
Original assignee: Siemens Aktiengesellschaft
Priority date: 2012-04-26
Filing date: 2013-04-17
Publication date: 2013-10-31
Also published as: BR112014026380A8; BR112014026380B1; EP2828011A1; EP2828011B1; EP2656932A1; CN104245166A; US20150122375A1; CN104245166B; US10131979B2; BR112014026380A2

Abstract

The invention relates to a method for reverse thermomechanically rolling an aluminium plate in a rolling process involving a plurality of rolling passes. In the method, identifying data (4) are determined for thermally guiding the rolling process; a value of a state variable (3), from which a temperature of the aluminium plate can be deduced, is continuously measured, and a pass schedule (5) is determined for the rolling process on the basis of the value of the measured state variable (3) and of the identifying data (4). The pass schedule (5) provides for a rolling pause between at least two successive rolling passes, during which rolling of the aluminium plate is interrupted for cooling purposes.

Description

description

Thermomechanical rolling of an aluminum plate

The invention relates to a method for the reversible thermomechanical rolling of an aluminum plate in a rolling process with several rolling passes.

Various methods for reversing thermomechanical rolling are known. WO 2008/043684, for example, discloses a method for tracking the physical state of a hot plate or strip as part of the control of a rolling train for reversibly machining a hot plate or strip. Here, at a starting ^¬ point, an initial state of the hot plate or hot strip from which a physical state quantity can be derived at least as determined in a model, and the state is cyclically updated during the processing of the hot plate using the model, wherein a displacement monitoring of the hot sheet or Hot bands and the state influencing and / or reproducing operating parameters are taken into account.

EP 2 111 309 B1 discloses a method for the thermomechanically controlled rolling of a batch of metal slabs into sheets or strips in a rolling mill with at least one rolling mill according to a rolling scheme which comprises at least two rolling phases and is applied to each slab of the batch. Currency ^¬ rend of rolling the batch at least one rolling mill stand it occurs several times that a different rolling phase followed by a rolling phase applied to one slab or plate or strip, which on another slab or plate or another tape This mill is applied. It is for two successively rolled slabs the time ^¬ span between the initial stages of their rolling phases always less than the sum of the durations of all rolling phases and all cooling phases of the rolling scheme. EP 1958711 Al discloses a method of thermo-mechanical controlled rolling of metal slabs, in which each metal slab during rolling at least two phases, which are interrupted by a cooling phase, rolled and several Me ^¬ tallbrammen are rolled simultaneously.

EP 2 305 392 A1 discloses a process for rolling rolling, wherein the rolling process comprises a cooling phase between two hot rolling transformations. During the cooling phase, a temperature difference between a central region and an edge region of the rolling stock is counteracted by heating the edge region.

The invention has for its object to provide an improved method for reversing thermomechanical rolling an aluminum plate.

The object is achieved by the features of claim 1. An ^¬ .

Advantageous embodiments of the invention are the subject of the dependent claims.

In the inventive method for reversing thermomechanical rolling an aluminum plate in a rolling process with a plurality of rolling passes characteristic data for the thermal management of the rolling process are specified and there are continuously values of at least one state variable from which a Tem ^¬ temperature of the aluminum plate is derivable, is determined. In Ab ^¬ dependence of the determined values of the at least one state variable and the characteristics of a pass schedule for the rolling process is determined, which provides a rolling pause aufeinan between at least two ^¬ the following rolling passes during which the rollers of the aluminum plate is interrupted at its cooling. At the same time, the characteristics associate at least one rolling pass with a waiting thickness of the aluminum plate, and the pass plan provides for the beginning of a rolling break as soon as the Thickness of the aluminum plate in the rolling pass reaches him fed ^¬ ordered waiting thickness or below.

An aluminum plate is understood in this application to mean a plate which consists of aluminum or an aluminum alloy.

As state variable, it is preferable to determine a temperature averaged over a thickness of the aluminum plate or a surface temperature or a residual solidification or phase portions or grain sizes or an enthalpy of the aluminum plate.

In the method according to the invention an aluminum plate is thus rolled temperature-controlled. Thereby, the temperature of the aluminum plate can be controlled and controlled during the rolling process. The control of the temperature takes place by means of rolling breaks, in which the aluminum plate is abge ^¬ cooled. This is advantageous because the rolling temperature be ^¬ can purportedly material properties of aluminum plates WE sentlich affected. Specifically, the temperature of the aluminum plate can be controlled during the rolling process so that the rolling subsequent known from the prior art post-processing steps for thermal Erzeu ^¬ supply certain mechanical properties of the material of the aluminum plate are unnecessary. Such manufacturing steps are ^¬ example, solution heat treating, quenching or curing the aluminum.

Furthermore, the insertion of rolling breaks is coupled to the achievement of predetermined thicknesses of the aluminum plate. As a result, a stepped rolling of the aluminum plate can advantageously be achieved, in which the rolling to cool the aluminum is interrupted by rolling breaks as a function of temperature and thickness of the aluminum plate.

A preferred embodiment of the invention provides that the characteristics of at least one rolling break assign a re-rolling temperature of the aluminum plate, and that the stitching plan to end this rolling break provides as soon as the Tempe ^¬ temperature of the aluminum plate reaches the Wiederanwalztemperatur. In this way it is achieved that the aluminum plate currency ^¬ rend a rolling pause cooled to a defined temperature, namely its associated Wiederanwalztemperatur. This advantageously improves the control and control of the temperature of the aluminum plate during the rolling process.

A further embodiment of the invention provides that the characteristics include a target temperature, and that the stitch plan a duration of a rolling break or a Wiederanwalztempe- rature of the aluminum plate after a rolling break ^¬ be such that the temperature of the aluminum plate after the last pass with the target temperature matches.

As a result, in addition to a defined final thickness, a target temperature of the aluminum plate can also be achieved in the last pass. This makes it possible to set advantageous Materialei ^¬ properties of aluminum already at the end of the rolling process without consuming post. In addition, can be counteracted by the target temperature at a suitable stitching strategy unwanted grain growth in the aluminum plate, which can adjust in conventional processes in a rolling process following the heat treatment.

A further embodiment of the invention provides that the characteristic data contain a cooling temperature, and that the aluminum plate is fed after the last rolling pass a cooling unit and cooled by the cooling unit to the cooling temperature. The characteristics preferably also include a cooling rate, and the aluminum plate is cooled to the cooling temperature at the cooling rate after the last rolling pass by means of the cooling unit. This advantageously allows to further improve the material properties of the aluminum after the rolling process by a controlled rate from ^¬ cooling. A particularly preferred embodiment of the invention provides that at least one rolling pass of another aluminum plate is carried out during at least one rolling break. For this purpose, for example, from EP 2 111 309 Bl known method for rolling multiple aluminum plates is used.

As a result, rolling breaks can be used advantageously for processing further aluminum plates, so that the utilization of a rolling train can be optimized. A further embodiment of the invention provides that a rolling force threshold value of a state variable of the aluminum plate is set as a function at least, and that the pass schedule that limits the rolling force during rolling in Depending ^¬ speed of the values of at least one state variable to the respective roll force threshold. Alternatively or additionally, a thickness degradation threshold value is set as a radio ^¬ tion of at least one state variable of the aluminum plate and through the pass schedule, the decrease in thickness of the aluminum plate during each reduction pass, the restricted in dependence on the values of at least one state variable to the respective thickness value of decrease threshold.

As a state variable, a thickness of the aluminum plate is preferably used. Alternatively or additionally, other geometric VARIAB ^¬ len, such as a curve or a profile of aluminum plate or thermodynamic variables, such as a temperature of the aluminum plate can be used as state variable. As a result, the material properties of the aluminum can be further improved and in particular an undesired grain growth in the aluminum plate can be counteracted. A further embodiment of the invention provides that the aluminum plate is cooled by a cooling unit during at least one rolling break. The use of cooling units for cooling the aluminum plate is advantageous because aluminum plates are usually rolled at relatively low temperatures and therefore passive cooling of the aluminum plates would cost too much time.

A further embodiment of the invention provides that continuously measured values of at least one are detected with a temperature of the aluminum ^¬ miniumplatte related measured variable and the values of evaluating temperature model to determine the at least one state variable on the basis of measured values acquired by means of these measured values. For determining a mo ^¬ mentanen temperature of the aluminum plate is particularly suitable from WO 2008/043684 a known method for tracking the physical state of the aluminum plate.

Such methods for determining a current temperature of the aluminum plate by means of a temperature model are particularly advantageous because a sufficiently ge ^¬ accurate direct measurement of a temperature of aluminum plates is usually difficult or too expensive and therefore He ^¬ ranziehung a model for temperature determination is useful ,

A further embodiment of the invention provides that the stitch plan is continuously updated, for example, after each pass of the aluminum plate by a cooling unit.

Such an update advantageously makes it possible, in the event of deviations from actual data, to make corrective use of plan data and to adapt the pass schedule to the current conditions. The above-described characteristics, features, and advantages of this invention, as well as the manner in which they will be achieved, will become clearer and more clearly understood in connection with the following description of exemplary embodiments, which will be described in connection with a drawing.

The figure shows a flow chart of a process performed by a car ^¬ matisierungssystems method for reversie- leaders thermomechanical rolling of an aluminum plate to an aluminum plate in a rolling process with a plurality of rolling passes.

In the method the measured values are 1 detects at least one egg with ^¬ ner temperature of the aluminum plate related measured variable. Such measurements are particularly tempera ^¬ ren at different locations of the aluminum plate and the aluminum plate as a structural characteristic quantities ^¬ structure.

3 as a state variable of the aluminum plate, an instantaneous temperature of the aluminum plate by means of the detected measured values by means of a 1, these measured values is 1 evaluating Temperaturmo ^¬ dells determined 2 of the aluminum plate, as seen from

WO 2008/043684 is known.

Furthermore, characteristic data 4 are predetermined for the thermal guidance of the rolling process and stored in the automation system. These characteristics include, in particular, waiting thicknesses, re-rolling temperatures, a target temperature, a cooling temperature, and a cooling rate.

On the basis of the determined instantaneous temperature of the aluminum plate and the characteristic data 4, a pass schedule 5 for the rolling process is determined, which also includes actuators 6 required to achieve the characteristics 4. Such actuators 6 include a cooling time in air cooling the aluminum plate, a number of rolling passes, a flow rate the aluminum plate through a rolling mill and / or amounts of water of a cooling unit.

On the basis of stitch plan 5, the aluminum plate is rolled during each rolling pass up to a waiting thickness assigned to the respective rolling pass. Subsequently, the rolling of the aluminum plate is interrupted by a rolling break until it has cooled to a rolling break associated Wiederanwalztemperatur the following roll pass. Here, the aluminum umplatte passively or actively abge ^¬ be cooled by a cooling unit. The waiting thicknesses and re-rolling temperatures depend on the material and the target geometry of the aluminum plate. These quantities can sometimes be derived from phase diagrams, for example in the case of aluminum plates made of aluminum-copper or aluminum-magnesium alloys, but are generally determined empirically.

The re-rolling temperature of the last rolling pass is determined on the basis of the temperature model 2 such that the temperature of the aluminum plate after the last rolling step coincides with the target temperature. The target temperature may e.g. by a temperature averaged over the thickness of the aluminum plate, a surface temperature or by a

Enthalpy can be characterized.

After the last pass, the aluminum plate is fed to a cooling unit and cooled by means of the cooling unit at the cooling rate to the cooling temperature. In one embodiment of the embodiment of pass schedule into consideration in addition to the characteristic data 4 for thermal management of the rolling process, other characteristics, such as a ma ^¬ ximum acting on the aluminum plate rolling force and / or a maximum thickness decrease of the aluminum plate during the individual rolling passes.

In a further, alternative or additional embodiment of the embodiment, the pass schedule is cyclical, For example, after each passage of the aluminum plate through a cooling unit, updated on the basis of the determined instantaneous temperature, in particular, the actuators 6 are updated for further cooling. In particular, can be taken from the plan data repeatedly correcting such a deviation of the actual data in order to achieve the targets (in particular a target thickness and the target temperature of the Alumini ^¬ umplatte). In a further, alternative or additional embodiment of the embodiment, at least one further aluminum plate is pre-rolled during the cooling of the aluminum plate in a rolling break. For this purpose, the method known from EP 2 111 309 B1 is used for the staggered rolling of a plurality of aluminum plates.

Although the invention has been further illustrated and described in detail by way of a preferred embodiment, the invention is not limited to the disclosed examples, and other variations can be derived therefrom by those skilled in the art without departing from the scope of the invention.

Claims

claims

A method for reversibly thermomechanical rolling an aluminum plate in a rolling process with multiple rolling passes, wherein

- characteristic data (4) are specified for the thermal guidance of the rolling process,

- a pass schedule (5) for the rolling process is determined and

the stitch plan (5) provides for a rolling break between at least two consecutive rolling passes during which the

Rolling the aluminum plate is interrupted to cool it,

characterized in that

- continuously values of at least one state variable (3), from which a temperature of the aluminum plate can be derived, are determined,

the pass schedule (5) for the rolling process is determined as a function of the determined values of the at least one state variable (3) and the characteristic data (4),

- The characteristic data (4) at least one Walzstich a Wartedi ^¬ bridge the aluminum plate assign, and

- the pass schedule provides for the start of a rolling break as soon as the thickness of the aluminum plate obtained in this rolling pass to him ^¬ orderly waiting thickness or below.

2. The method according to claim 1,

characterized in that the characteristic data (4) at least ei ^¬ ner rolling break assign a Wiederanwalztemperatur the aluminum plate, and that the pass schedule provides for the termination of this rolling break as soon as the temperature of the aluminum plate reaches the ^¬ deranwalztemperatur.

3. The method according to any one of the preceding claims,

characterized in that the characteristic data (4) contain a target temperature, and that the pass schedule has a duration of

Walzpause or Wiederanwalztemperatur the aluminum plate after a rolling break so determined that the temperature the aluminum plate after the last pass matches the target temperature.

4. The method according to any one of the preceding claims,

characterized in that a is determined by a thickness of the aluminum plate averaged temperature or egg ^¬ ne surface temperature or residual solidification or phase fractions or particle sizes or enthalpy of the aluminum plate as a state variable (3).

5. The method according to any one of the preceding claims,

characterized in that the characteristic data (4) contain a cooling temperature, and that the aluminum plate is fed to a cooling unit after the last pass and is cooled by means of the cooling unit to the cooling temperature.

6. The method according to claim 5,

characterized in that the characteristic data (4) include a cooling rate, and that the aluminum plate is cooled after the last rolling pass by means of the cooling unit at the cooling rate to the cooling temperature.

7. The method according to any one of the preceding claims,

characterized in that during at least one rolling break at least one rolling pass of another aluminum plate is performed.

8. The method according to any one of the preceding claims,

characterized in that a rolling force threshold value is set as a function of at least one state variable of the Aluminiumplat ^¬ te, and that the pass schedule of rolling as a function of the values of Wenig ^¬ least restricts the rolling force currency ^¬ rend a state variable on the respective roll force ^¬ threshold.

9. The method according to any one of the preceding claims,

characterized in that a thickness decrease threshold value as a function of at least one state variable of the aluminum and that the stitching plan restricts the decrease in a thickness of the aluminum plate during each rolling pass depending on the values of the at least one state variable to the respective thickness decrease threshold value.

10. The method according to claim 8 or 9,

characterized in that a thickness of the aluminum plate is used as a state variable.

11. The method according to any one of the preceding claims, characterized in that the aluminum plate is cooled during we ^¬ least one rolling break by a cooling unit.

12. The method as claimed in claim 1, characterized in that measured values (1) of at least one measured variable associated with a temperature of the aluminum plate are continuously recorded, and the values of the at least one state variable (3) are recorded on the basis of the detected measured values (1) by means of one of these measured values (1) evaluating Temperaturmo ^¬ dells (2) are determined.

13. The method according to any one of the preceding claims, characterized in that the pass schedule (5) is updated constantly.